Hydrogen bond network analysis reveals the pathway for the proton transfer in the E-channel of T. thermophilus Complex I

Complex I, NADH-ubiquinone oxidoreductase, is the first enzyme in the mitochondrial and bacterial aerobic respiratory chain. It pumps four protons through four transiently open pathways from the high pH, negative, N-side of the membrane to the positive, P-side driven by the exergonic transfer of electrons from NADH to a quinone. Three protons transfer through subunits descended from antiporters, while the fourth, E-channel is unique. The path through the E-channel is determined by a network analysis of hydrogen bonded pathways obtained by Monte Carlo sampling of protonation states, polar hydrogen orientation and water occupancy. Input coordinates are derived from molecular dynamics trajectories comparing oxidized, reduced (dihydro) and no menaquinone-8 (MQ). A complex proton transfer path from the N- to the P-side is found consisting of six clusters of highly connected hydrogen-bonded residues. The network connectivity depends on the presence of quinone and its redox state, supporting a role for this cofactor in coupling electron and proton transfers. The N-side is more organized with MQ-bound complex I facilitating proton entry, while the P-side is more connected in the apo-protein, facilitating proton exit. Subunit Nqo8 forms the core of the E channel; Nqo4 provides the N-side entry, Nqo7 and then Nqo10 join the pathway in the middle, while Nqo11 contributes to the P-side exit.     

Identifying the proton loading site cluster in the ba3 cytochrome c oxidase that loads and traps protons

Cytochrome c Oxidase (CcO) is the terminal electron acceptor in aerobic respiratory chain, reducing O₂ to water. The released free energy is stored by pumping protons through the protein, maintaining the transmembrane electrochemical gradient. Protons are held transiently in a proton loading site (PLS) that binds and releases protons driven by the electron transfer reaction cycle. Multi-Conformation Continuum Electrostatics (MCCE) was applied to crystal structures and Molecular Dynamics snapshots of the B-type Thermus thermophilus CcO. Six residues are identified as the PLS, binding and releasing protons as the charges on heme b and the binuclear center are changed: the heme a₃ propionic acids, Asp287, Asp372, His376 and Glu126B. The unloaded state has one proton and the loaded state two protons on these six residues. Different input structures, modifying the PLS conformation, show different proton distributions and result in different proton pumping behaviors. One loaded and one unloaded protonation states have the loaded/unloaded states close in energy so the PLS binds and releases a proton through the reaction cycle. The alternative proton distributions have state energies too far apart to be shifted by the electron transfers so are locked in loaded or unloaded states. Here the protein can use active states to load and unload protons, but has nearby trapped states, which stabilize PLS protonation state, providing new ideas about the CcO proton pumping mechanism. The distance between the PLS residues Asp287 and His376 correlates with the energy difference between loaded and unloaded states.     

Expanding the view of proton pumping in cytochrome c oxidase through computer simulation

In cytochrome c oxidase (CcO), a redox-driven proton pump, protons are transported by the Grotthuss shuttling via hydrogen-bonded water molecules and protonatable residues. Proton transport through the D-pathway is a complicated process that is highly sensitive to alterations in the amino acids or the solvation structure in the channel, both of which can inhibit proton pumping and enzymatic activity. Simulations of proton transport in the hydrophobic cavity showed a clear redox state dependence. To study the mechanism of proton pumping in CcO, multi-state empirical valence bond (MS-EVB) simulations have been conducted, focusing on the proton transport through the D-pathway and the hydrophobic cavity next to the binuclear center. The hydration structures, transport pathways, effects of residues, and free energy surfaces of proton transport were revealed in these MS-EVB simulations. The mechanistic insight gained from them is herein reviewed and placed in context for future studies.     

The protonation state of a heme propionate controls electron transfer in cytochrome c oxidase

In cytochrome c oxidase (CcO), exergonic electron transfer reactions from cytochrome c to oxygen drive proton pumping across the membrane. Elucidation of the proton pumping mechanism requires identification of the molecular components involved in the proton transfer reactions and investigation of the coupling between internal electron and proton transfer reactions in CcO. While the proton-input trajectory in CcO is relatively well characterized, the components of the output pathway have not been identified in detail. In this study, we have investigated the pH dependence of electron transfer reactions that are linked to proton translocation in a structural variant of CcO in which Arg481, which interacts with the heme D-ring propionates in a proposed proton output pathway, was replaced with Lys (RK481 CcO). The results show that in RK481 CcO the midpoint potentials of hemes a and a(3) were lowered by approximately 40 and approximately 15 mV, respectively, which stabilizes the reduced state of Cu(A) during reaction of the reduced CcO with O(2). In addition, while the pH dependence of the F --> O rate in wild-type CcO is determined by the protonation state of two protonatable groups with pK(a) values of 6.3 and 9.4, only the high-pK(a) group influences this rate in RK481 CcO. The results indicate that the protonation state of the Arg481 heme a(3) D-ring propionate cluster having a pK(a) of approximately 6.3 modulates the rate of internal electron transfer and may act as an acceptor of pumped protons.     

The proton pumping mechanism of the bc1 complex

The bc₁ complex is a proton pump of the mitochondrial electron transport chain which transfers electrons from ubiquinol to cytochrome c. It operates via the modified Q cycle in which the two electrons from oxidation of ubiquinol at the Q_o center are bifurcated such that the first electron is passed to Cytc via an iron sulfur center and c₁ whereas the second electron is passed across the membrane by b_L and b_H to reduce ubiquinone at the Q_i center. Proton pumping occurs because oxidation of ubiquinol at the Q_o center releases protons to the P-side and reduction of ubiquinone at the Q_i center takes up protons from the N-side. However, the mechanisms which prevent the thermodynamically more favorable short circuit reactions and so ensure precise bifurcation and proton pumping are not known. Here we use statistical thermodynamics to show that reaction steps that originate from high energy states cannot support high flux even when they have large rate constants. We show how the chemistry of ubiquinol oxidation and the structure of the Q_o site can result in free energy profiles that naturally suppress flux through the short circuit pathways while allowing high rates of bifurcation. These predictions are confirmed through in-silico simulations using a Markov state model.     

The pore-lining regions in cytochrome c oxidases: A computational analysis of caveolin,cholesterol and transmembrane helix contributions to proton movement

Cytochrome c oxidase (CcO) is the terminal enzyme in the electron transfer chain. CcO catalyzes a four electron reduction of O₂ to water at a catalytic site formed by high-spin heme (a₃) and copper atoms (Cu_B). While it is recognized that proton movement is coupled to oxygen reduction, the proton channel(s) have not been well defined. Using computational methods developed to study protein topology, membrane channels and 3D packing arrangements within transmembrane (TM) helix arrays, we find that subunit-1 (COX-1), subunit-2 (COX-2) and subunit-3 (COX-3) contribute 139, 46 and 25 residues, respectively, to channel formation between the mitochondrial matrix and intermembrane space. Nine of 12 TM helices in COX-1, both helices in COX-2 and 5 of the 6 TM helices in COX-3 are pore-lining regions (possible channel formers). Heme a₃ and the Cu_B sites (as well as the Cu_A center of COX-2) are located within the channel that includes TM-6, TM-7, TM-10 and TM-11 of COX-1 and are associated with multiple cholesterol and caveolin-binding (CB) motifs. Sequence analysis identifies five CB motifs within COX-1, two within COX-2 and four within COX-3; each caveolin containing a pore-lining helix C-terminal to a TM helix–turn–helix. Channel formation involves interaction between multiple pore-lining regions within protein subunits and/or dimers. PoreWalker analysis lends support to the D-channel model of proton translocation. Under physiological conditions, caveolins may introduce channel formers juxtaposed to those in COX-1, COX-2 and COX-3, which together with cholesterol may form channel(s) essential for proton translocation through the inner mitochondrial membrane.     

Effective Pumping Proton Collection Facilitated by a Copper Site (CuB) of Bovine Heart Cytochrome c Oxidase,Revealed by a Newly Developed Time-resolved Infrared System

X-ray structural and mutational analyses have shown that bovine heart cytochrome c oxidase (CcO) pumps protons electrostatically through a hydrogen bond network using net positive charges created upon oxidation of a heme iron (located near the hydrogen bond network) for O₂ reduction. Pumping protons are transferred by mobile water molecules from the negative side of the mitochondrial inner membrane through a water channel into the hydrogen bond network. For blockage of spontaneous proton back-leak, the water channel is closed upon O₂ binding to the second heme (heme a₃) after complete collection of the pumping protons in the hydrogen bond network. For elucidation of the structural bases for the mechanism of the proton collection and timely closure of the water channel, conformational dynamics after photolysis of CO (an O₂ analog)-bound CcO was examined using a newly developed time-resolved infrared system feasible for accurate detection of a single C=O stretch band of α-helices of CcO in H₂O medium. The present results indicate that migration of CO from heme a₃ to Cu_B in the O₂ reduction site induces an intermediate state in which a bulge conformation at Ser-382 in a transmembrane helix is eliminated to open the water channel. The structural changes suggest that, using a conformational relay system, including Cu_B, O₂, heme a₃, and two helix turns extending to Ser-382, Cu_B induces the conformational changes of the water channel that stimulate the proton collection, and senses complete proton loading into the hydrogen bond network to trigger the timely channel closure by O₂ transfer from Cu_B to heme a₃.     

Net proton uptake is preceded by multiple proton transfer steps upon electron injection into cytochrome c oxidase

Cytochrome c oxidase (COX), the last enzyme of the respiratory chain of aerobic organisms, catalyzes the reduction of molecular oxygen to water. It is a redox-linked proton pump, whose mechanism of proton pumping has been controversially discussed, and the coupling of proton and electron transfer is still not understood. Here, we investigated the kinetics of proton transfer reactions following the injection of a single electron into the fully oxidized enzyme and its transfer to the hemes using time-resolved absorption spectroscopy and pH indicator dyes. By comparison of proton uptake and release kinetics observed for solubilized COX and COX-containing liposomes, we conclude that the 1-μs electron injection into Cu(A), close to the positive membrane side (P-side) of the enzyme, already results in proton uptake from both the P-side and the N (negative)-side (1.5 H(+)/COX and 1 H(+)/COX, respectively). The subsequent 10-μs transfer of the electron to heme a is accompanied by the release of 1 proton from the P-side to the aqueous bulk phase, leaving ～0.5 H(+)/COX at this side to electrostatically compensate the charge of the electron. With ～200 μs, all but 0.4 H(+) at the N-side are released to the bulk phase, and the remaining proton is transferred toward the hemes to a so-called "pump site." Thus, this proton may already be taken up by the enzyme as early as during the first electron transfer to Cu(A). These results support the idea of a proton-collecting antenna, switched on by electron injection.     

Energy diagrams and mechanism for proton pumping in cytochrome c oxidase

The powerful technique of energy diagrams has been used to analyze the mechanism for proton pumping in cytochrome c oxidase. Energy levels and barriers are derived starting out from recent kinetic experiments for the O to E transition, and are then refined using general criteria and a few additional experimental facts. Both allowed and non-allowed pathways are obtained in this way. A useful requirement is that the forward and backward rate should approach each other for the full membrane gradient. A key finding is that an electron on heme a (or the binuclear center) must have a significant lowering effect on the barrier for proton uptake, in order to prevent backflow from the pump-site to the N-side. While there is no structural gating in the present mechanism, there is thus an electronic gating provided by the electron on heme a. A quantitative analysis of the energy levels in the diagrams, leads to Prop-A of heme a₃ as the most likely position for the pump-site, and the Glu278 region as the place for the transition state for proton uptake. Variations of key redox potentials and pK_a values during the pumping process are derived for comparison to experiments.     

Modulation of the electron-proton coupling at cytochrome a by the ligation of the oxidized catalytic center in bovine cytochrome c oxidase

Cytochrome a was suggested as the key redox center in the proton pumping process of bovine cytochrome c oxidase (CcO). Recent studies showed that both the structure of heme a and its immediate vicinity are sensitive to the ligation and the redox state of the distant catalytic center composed of iron of cytochrome a₃ (Fe_a3) and copper (Cu_B). Here, the influence of the ligation at the oxidized Fe_a3³⁺–Cu_B²⁺ center on the electron–proton coupling at heme a was examined in the wide pH range (6.5-11). The strength of the coupling was evaluated by the determination of pH dependence of the midpoint potential of heme a (E_m(a)) for the cyanide (the low-spin Fe_a3³⁺) and the formate-ligated CcO (the high-spin Fe_a3³⁺). The measurements were performed under experimental conditions when other three redox centers of CcO are oxidized. Two slightly differing linear pH dependencies of E_m(a) were found for the CN– and the formate–ligated CcO with slopes of −13 mV/pH unit and −23 mV/pH unit, respectively. These linear dependencies indicate only a weak and unspecific electron–proton coupling at cytochrome a in both forms of CcO. The lack of the strong electron–proton coupling at the physiological pH values is also substantiated by the UV–Vis absorption and electron–paramagnetic resonance spectroscopy investigations of the cyanide–ligated oxidized CcO. It is shown that the ligand exchange at Fe_a³⁺ between His–Fe_a³⁺–His and His–Fe_a³⁺–OH⁻ occurs only at pH above 9.5 with the estimated pK >11.0.     

Critical roles of the CuB site in efficient proton pumping as revealed by crystal structures of mammalian cytochrome c oxidase catalytic intermediates

Mammalian cytochrome c oxidase (CcO) reduces O₂ to water in a bimetallic site including Fe_a3 and Cu_B giving intermediate molecules, termed A-, P-, F-, O-, E-, and R-forms. From the P-form on, each reaction step is driven by single-electron donations from cytochrome c coupled with the pumping of a single proton through the H-pathway, a proton-conducting pathway composed of a hydrogen-bond network and a water channel. The proton-gradient formed is utilized for ATP production by F-ATPase. For elucidation of the proton pumping mechanism, crystal structural determination of these intermediate forms is necessary. Here we report X-ray crystallographic analysis at ∼1.8 Å resolution of fully reduced CcO crystals treated with O₂ for three different time periods. Our disentanglement of intermediate forms from crystals that were composed of multiple forms determined that these three crystallographic data sets contained ∼45% of the O-form structure, ∼45% of the E-form structure, and ∼20% of an oxymyoglobin-type structure consistent with the A-form, respectively. The O- and E-forms exhibit an unusually long Cu_B²⁺-OH⁻ distance and Cu_B¹⁺-H₂O structure keeping Fe_a3³⁺-OH⁻ state, respectively, suggesting that the O- and E-forms have high electron affinities that cause the O→E and E→R transitions to be essentially irreversible and thus enable tightly coupled proton pumping. The water channel of the H-pathway is closed in the O- and E-forms and partially open in the R-form. These structures, together with those of the recently reported P- and F-forms, indicate that closure of the H-pathway water channel avoids back-leaking of protons for facilitating the effective proton pumping.     

Redox-linked protonation state changes in cytochrome bc1 identified by Poisson-Boltzmann electrostatics calculations

Cytochrome bc₁ is a major component of biological energy conversion that exploits an energetically favourable redox reaction to generate a transmembrane proton gradient. Since the mechanistic details of the coupling of redox and protonation reactions in the active sites are largely unresolved, we have identified residues that undergo redox-linked protonation state changes. Structure-based Poisson-Boltzmann/Monte Carlo titration calculations have been performed for completely reduced and completely oxidised cytochrome bc₁. Different crystallographically observed conformations of Glu272 and surrounding residues of the cytochrome b subunit in cytochrome bc₁ from Saccharomyces cerevisiae have been considered in the calculations. Coenzyme Q (CoQ) has been modelled into the CoQ oxidation site (Q_o-site). Our results indicate that both conformational and protonation state changes of Glu272 of cytochrome b may contribute to the postulated gating of CoQ oxidation. The Rieske iron-sulphur cluster could be shown to undergo redox-linked protonation state changes of its histidine ligands in the structural context of the CoQ-bound Q_o-site. The proton acceptor role of the CoQ ligands in the CoQ reduction site (Q_i-site) is supported by our results. A modified path for proton uptake towards the Q_i-site features a cluster of conserved lysine residues in the cytochrome b (Lys228) and cytochrome c₁ subunits (Lys288, Lys289, Lys296). The cardiolipin molecule bound close to the Q_i-site stabilises protons in this cluster of lysine residues.     

Free energy profiles for H conduction in the D-pathway of Cytochrome c Oxidase: A study of the wild type and N98D mutant enzymes

The molecular mechanism for proton conduction in the D-pathway of Cytochrome c Oxidase (CcO) is investigated through the free energy profile, i.e., potential of mean force (PMF) calculations of both the native enzyme and the N98D mutant. The multistate empirical valence bond (MS-EVB) model was applied to simulate the interaction of an excess proton with the channel environment. In the study of the wild type enzyme, the PMF reveals the previously proposed proton trap inside the channel; it also shows a high free energy barrier against the passage of proton at the entry of the channel, where two conserved asparagines (ASN80/98) may be essential for the gating of proton uptake. We also present data from an investigation of the N98D mutant, which has been previously shown to completely eliminate proton pumping but significantly enhance the oxidase activity in Rhodobacter sphaeroides. These results suggest that mutating Asn98 to negatively charged aspartate will create an unfavorable energy barrier sufficiently high to prevent the overall proton uptake through the D-pathway, whereas with a protonated aspartic acid the proton conduction was found to be accelerated. Plausible explanations for the origin of the uncoupling of proton pumping from the oxidase activity will be discussed.     

Investigation of protonatable residues in Rhodothermus marinus caa 3 haem-copper oxygen reductase: comparison with Paracoccus denitrificans aa 3 haem-copper oxygen reductase

The Rhodothermus marinus caa ₃ haem-copper oxygen reductase contains all the residues of the so-called D- and K-proton channels, with the notable exception of the helix VI glutamate residue (Glu278^I in Paracoccus denitrificans aa ₃), being nevertheless a true oxygen reductase reducing O₂ to water, and an efficient proton pump. Instead, in the same helix, but one turn below, it has a tyrosine residue (Tyr256^I, R. marinus caa ₃ numbering), whose hydroxyl group occupies the same spatial position as the carboxylate group of Glu278^I, as deduced by comparative modelling techniques. Therefore, we proposed previously that this tyrosine residue could play an important role in the proton pathway. In this article we further study this hypothesis, by investigating the equilibrium thermodynamics of protonation in R. marinus caa ₃, using theoretical methodologies based on the structural model previously obtained. Control calculations are also performed for the P. denitrificans aa ₃ oxygen reductase. In both oxygen reductases we find several residues that are proton active (i.e., that display partial protonation) at physiological pH, some of them being redox sensitive (i.e., sensitive to the protein redox state). However, the caa ₃ Tyr256^I is not proton active at physiological pH, in contrast to the aa ₃ Glu278^I which is both proton active at physiological pH and shows a high redox sensitivity. In R. marinus caa ₃ we do not find any other residues in the same protein zone that can have this property. Therefore, there are no putative D-channel residues that are proton active in this oxidase. The protonatable residues of the K-channel are much more functionally conserved in both oxygen reductases than the same type of residues in the D-channel. Two (Tyr262^I and Lys336^I, caa ₃ numbering) out of three protonatable K-channel residues are proton active and redox sensitive in both proteins.     

Modulation of the Respiratory Supercomplexes in Yeast: ENHANCED FORMATION OF CYTOCHROME OXIDASE INCREASES THE STABILITY AND ABUNDANCE OF RESPIRATORY SUPERCOMPLEXES*

Yeast cells deficient in the Rieske iron-sulfur subunit (Rip1) of ubiquinol-cytochrome c reductase (bc₁) accumulate a late core assembly intermediate, which weakly associates with cytochrome oxidase (CcO) in a respiratory supercomplex. Expression of the N-terminal half of Rip1, which lacks the C-terminal FeS-containing globular domain (designated N-Rip1), results in a marked stabilization of trimeric and tetrameric bc₁-CcO supercomplexes. Another bc₁ mutant (qcr9Δ) stalled at the same assembly intermediate is likewise converted to stable supercomplex species by the expression of N-Rip1, but not by expression of intact Rip1. The N-Rip1-induced stabilization of bc₁-CcO supercomplexes is independent of the Bcs1 translocase, which mediates Rip1 translocation during bc₁ biogenesis. N-Rip1 induces the stabilization of bc₁-CcO supercomplexes through an enhanced formation of CcO. The association of N-Rip1 with the late core bc₁ assembly intermediate appears to confer stabilization of a CcO assembly intermediate. This induced stabilization of CcO is dependent on the Rcf1 supercomplex stabilization factor and only partially dependent on the presence of cardiolipin. N-Rip1 exerts a related induction of CcO stabilization in WT yeast, resulting in enhanced respiration. Additionally, the impact of CcO stabilization on supercomplexes was observed by means other than expression of N-Rip1 (via overexpression of CcO subunits Cox4 and Cox5a), demonstrating that this is a general phenomenon. This study presents the first evidence showing that supercomplexes can be stabilized by the stimulated formation of CcO.     

Redox-Bohr effect in electron/proton energy transduction: cytochrome c 3 coupled to hydrogenase works as a 'proton thruster' in Desulfovibrio vulgaris

 A central step in the metabolism of Desulfovibrio spp. is the oxidation of molecular hydrogen catalyzed by a periplasmic hydrogenase. However, this enzymatic activity is quite low at physiological pH. The hypothesis that, in the presence of the tetrahaem cytochrome c ₃, hydrogenase can maintain full activity at physiological pH through the concerted capture of the resulting electrons and protons by the cytochrome was tested for the case of Desulfovibrio vulgaris (Hildenborough). The crucial step involves an electron-to-proton energy transduction, and is achieved through a network of cooperativities between redox and ionizable centers within the cytochrome (redox-Bohr effect). This mechanism, which requires a relocation of the proposed proton channel in the hydrogenase structure, is similar to that proposed for the transmembrane proton pumps, and is the first example which shows evidence of functional energy transduction in the absence of a membrane confinement. Received: 2 April 1997 / Accepted: 23 May 1997     

Redox-coupled proton transfer in the active site of cytochrome cbb3

Cytochrome cbb₃ is a distinct member of the superfamily of respiratory heme-copper oxidases, and is responsible for driving the respiratory chain in many pathogenic bacteria. Like the canonical heme-copper oxidases, cytochrome cbb₃ reduces oxygen to water and couples the released energy to pump protons across the bacterial membrane. Homology modeling and recent electron paramagnetic resonance (EPR) studies on wild type and a mutant cbb₃ enzyme [V. Rauhamäki et al. J. Biol. Chem. 284 (2009) 11301-11308] have led us to perform high-level quantum chemical calculations on the active site. These calculations bring molecular insight into the unique hydrogen bonding between the proximal histidine ligand of heme b₃ and a conserved glutamate, and indicate that the catalytic mechanism involves redox-coupled proton transfer between these residues. The calculated spin densities give insight in the difference in EPR spectra for the wild type and a recently studied E383Q-mutant cbb₃-enzyme. Furthermore, we show that the redox-coupled proton movement in the proximal cavity of cbb₃-enzymes contributes to the low redox potential of heme b₃, and suggest its potential implications for the high apparent oxygen affinity of these enzymes.     

The D-channel of cytochrome oxidase: an alternative view

The D-pathway in A-type cytochrome c oxidases conducts protons from a conserved aspartate on the negatively charged N-side of the membrane to a conserved glutamic acid at about the middle of the membrane dielectric. Extensive work in the past has indicated that all four protons pumped across the membrane on reduction of O(2) to water are transferred via the D-pathway, and that it is also responsible for transfer of two out of the four "chemical protons" from the N-side to the binuclear oxygen reduction site to form product water. The function of the D-pathway has been discussed in terms of an apparent pK(a) of the glutamic acid. After reacting fully reduced enzyme with O(2), the rate of formation of the F state of the binuclear heme-copper active site was found to be independent of pH up to pH~9, but to drop off at higher pH with an apparent pK(a) of 9.4, which was attributed to the glutamic acid. Here, we present an alternative view, according to which the pH-dependence is controlled by proton transfer into the aspartate residue at the N-side orifice of the D-pathway. We summarise experimental evidence that favours a proton pump mechanism in which the proton to be pumped is transferred from the glutamic acid to a proton-loading site prior to proton transfer for completion of oxygen reduction chemistry. The mechanism is discussed by which the proton-pumping activity is decoupled from electron transfer by structural alterations of the D-pathway. This article is part of a Special Issue entitled: Allosteric cooperativity in respiratory proteins.     

The Carboxyl-terminal End of Cox1 Is Required for Feedback Assembly Regulation of Cox1 Synthesis in Saccharomyces cerevisiae Mitochondria

Synthesis of the largest cytochrome c oxidase (CcO) subunit, Cox1, on yeast mitochondrial ribosomes is coupled to assembly of CcO. The translational activator Mss51 is sequestered in early assembly intermediate complexes by an interaction with Cox14 that depends on the presence of newly synthesized Cox1. If CcO assembly is prevented, the level of Mss51 available for translational activation is reduced. We deleted the C-terminal 11 or 15 residues of Cox1 by site-directed mutagenesis of mtDNA. Although these deletions did not prevent respiratory growth of yeast, they eliminated the assembly-feedback control of Cox1 synthesis. Furthermore, these deletions reduced the strength of the Mss51-Cox14 interaction as detected by co-immunoprecipitation, confirming the importance of the Cox1 C-terminal residues for Mss51 sequestration. We surveyed a panel of mutations that block CcO assembly for the strength of their effect on Cox1 synthesis, both by pulse labeling and expression of the ARG8_m reporter fused to COX1. Deletion of the nuclear gene encoding Cox6, one of the first subunits to be added to assembling CcO, caused the most severe reduction in Cox1 synthesis. Deletion of the C-terminal 15 amino acids of Cox1 increased Cox1 synthesis in the presence of each of these mutations, except pet54. Our data suggest a novel activity of Pet54 required for normal synthesis of Cox1 that is independent of the Cox1 C-terminal end.